The Role of the 3-Dimensional Genome in New Gene Evolution

ABSTRACT

In efforts to explain how duplicate gene copies may rise to fixation in a population, previous models of new gene origination have underappreciated the importance of the 3D genome in this process. We show that proximity-based regulatory recruitment in distally duplicated genes, i.e. enhancer capture, is an efficient mechanism for accommodation of new selective conditions. By performing a co-expression analysis on D. melanogaster tissue data and comparing essential to non-essential genes that have newly evolved, we show that enhancer capture is a significant driver of new gene evolution in distally duplicated genes. The new essential gene, HP6/Umbrea, is used as a model for understanding enhancer capture, as it evolved via a full duplication of the parental gene, its subsequent protein evolution is known, and it duplicated into a gene-poor region of the genome. HP6/Umbrea’s expression pattern divergence from its parental gene, HP1b, as well as its high co-expression with neighboring genes suggest that it evolved via enhancer capture. ChIP-Seq data shows the presence of active enhancer marks appearing near HP6/Umbrea coinciding with onset of its expression which likely regulates HP6/Umbrea, its neighboring gene, as well as a distally located 6-gene cluster also found co-express with HP6/Umbrea. We find that these three loci, the putative enhancer, HP6/Umbrea, and the 6-gene cluster are in close physical proximity in the 3-D genome of D. melanogaster. Finally, we compare Hi-C data from two species with HP6/Umbrea, D. melanogaster and D. yakuba, to two species pre-dating HP6/Umbrea’s insertion, D. pseudoobscura and D. miranda, showing that co-regulation of these same elements is the ancestral state and thus that HP6/Umbrea evolved via enhancer capture.